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Pharmacogenomics, personalized medicine and the drug development process.

Pharmacogenomics, personalized medicine and the drug development process. Michael G. Walker, Ph.D. www.walkerbioscience.com mwalker@stanfordalumni.org 408 234-8971. Topics. The need for personalized medicine Drug development aspects Case studies Genomic Health PharmGKB Theranos

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Pharmacogenomics, personalized medicine and the drug development process.

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  1. Pharmacogenomics, personalized medicine and the drug development process. Michael G. Walker, Ph.D. www.walkerbioscience.com mwalker@stanfordalumni.org 408 234-8971

  2. Topics • The need for personalized medicine • Drug development aspects • Case studies • Genomic Health • PharmGKB • Theranos • Technical issues: SNP’s, expression, environment • Statistics issues: sample size, validation

  3. The medical need for personalized medicine • Problem: The narrow “therapeutic window” dosing range for drugs. • Patients suffer from adverse events or ineffective drugs. Can we predict who and adjust therapy? • Drugs fails for adverse events or lack of efficacy. Can we rescue drugs that benefit the great majority?

  4. Drug development aspects of personalized medicine • Drugs fail in clinical trials because of adverse events or lack of efficacy. • Need: Identify the genetic and environmental factors that determine which patients have lack of efficacy, which will have adverse events. • Bring safer, more effective drugs to market. • Save drugs that might otherwise fail to gain approval. • Design drugs for patients based on genetic & genomic information

  5. Case studies • Genomic Health • PharmGKB • Theranos

  6. New England Journal of Medicine 2004; 351:2817-26.

  7. Current Cancer Treatment • 15% of women with node -ve, ER+ breast cancer will have a distant recurrence. • But 50% of node –ve, ER+ women receive chemotherapy, with its attendant morbidity, mortality, and cost • Can we identify those women who will not benefit from and don’t need chemo?

  8. Steps in assay development Candidate Gene Selection (Microarrays & published literature) Clinical Testing Studies (RT-PCR) Clinical Validation Studies (RT-PCR) CLIA Lab Service (RT-PCR)

  9. Assay development and validation studies • Three studies for gene selection and algorithm development: • Providence • Rush • NSABP B20 • One prospective validation study: • NSABP B14

  10. Providence Medical Center Study:Tumor gene expression in early-stage breast cancer In collaboration with J. Esteban et al Providence-St. Joseph Medical Center, Burbank

  11. Specific Objectives • Explore correlation between RNA expression in primary tumor blocks for 185 candidate genes and likelihood of breast cancer recurrence • Lead to design of a multi-gene assay to be used in large Clinical Validation studies

  12. Study Design • 136 eligible patients with sufficient sample • Invasive breast cancer • Surgery between 1/1/90 and 12/31/97 • Primary tumor block available • Sufficient tumor (>20% of section invasive cancer)

  13. Gene Expression and Prognosis Univariate Cox proportional hazards analysis 45 genes prognostic of recurrence (p < 0.05) Direction of gene expression is, in general, biologically plausible

  14. Expected clusters of co-expressed genes were found ER Proliferation HER2 Immune/Invasion Cluster Analysis--Genes

  15. Rush study:Tumor gene expression in breast cancer patients with 10 or more positive nodes In collaboration with Melody A. Cobleigh et al. Rush-Presbyterian-St Luke's Med Ctr

  16. Specific Objective • Rush-Genomic Health Study is second of three Clinical Testing studies that: • Explore correlation between RNA expression in primary tumor blocks for 187 candidate genes and likelihood of breast cancer recurrence • Lead to design of a multi-gene assay to be used in large Clinical Validation studies

  17. Rush: Univariate Cox proportional hazards analysis 21 genes predict likelihood of recurrence (p < 0.05) Includes related genes and signaling pathways such as: ER (e.g., PR, Bcl2, ER, CEGP1) HER2 (e.g., HER2, Grb7) Effect of gene expression is generally is the “right” direction Higher expression of the HER2 and Grb7 are associated with higher risk Higher expression of the ER genes are associated with lower risk

  18. Rush: Clinical Variables, Gene Expression and Prognosis Gene expression is the strongest predictor of outcome, independent of clinical variables, including the number of involved nodes

  19. Rush: Gene Expression and Prognosis Low HER2 expression High HER2 expression Single Gene Model (pts separated into tertiles by HER2 expression) Multi-Gene Model (pts separated into tertiles)

  20. NSABP B20 study • Third screening study to identify candidate genes • Results were combined with Rush and Providence to identify genes that were significant predictors across all studies • Led to development of Recurrence Score to predict breast cancer recurrence

  21. Algorithm development I • Determine appropriate number of terms in final model using bootstrap and stepwise variable selection in B20 • Select statistically significant genes in Cox survival analyses in three studies • Create new variables from correlated genes (proliferation, ER, Her2 groups)

  22. Algorithm development II • Based on analysis of Martingale residuals, create non-linear (threshold) functional forms • Fit model to NSABP B20 data with specified number of terms and specified functional forms. • Apply Bayesian parameter adjustments. • Define thresholds for low, moderate, and high risk groups

  23. Three Breast Cancer Studies Used to Select 16 Cancer and 5 Reference Genes PROLIFERATION Ki-67 STK15 Survivin Cyclin B1 MYBL2 ESTROGEN ER PGR Bcl2 SCUBE2 HER2 GRB7 HER2 GSTM1 REFERENCE Beta-actin GAPDH RPLPO GUS TFRC INVASION Stromolysin 3 Cathepsin L2 CD68 BAG1 Best RT-PCR performance and most robust predictors

  24. Three Breast Cancer Studies Used to Develop Recurrence Score (RS) Algorithm Three Breast Cancer Studies Used to Develop Recurrence Score (RS) Algorithm

  25. Genomic Health-NSABP B-14 Prospective Clinical Validation Study • Objective • Validate Recurrence Score as predictor of distant recurrence in N-, ER+, tamoxifen-treated patients • Design • Pre-specified 21 gene assay, algorithm, endpoints, analysis plan • Blinded laboratory analysis of three 10 µ sections Placebo--Not Eligible Randomized Tamoxifen--Eligible B-14 Registered Tamoxifen--Eligible

  26. B-14 - Subjects Evaluable Patients • 2617 tamoxifen-treated eligible patients in B-14 • 675 pathology eligible patients and RT-PCR performed—block never obtained or insufficient tumor in block in remaining cases • Insufficient RNA or RT-PCR outside of specifications • 7 pts (1%) • Evaluable patients in final analysis • 668 pts (99%)

  27. p=0.23 p=0.16 B-14 Evaluable Patients (n=668) Similar to All Patients (n=2617) Eval (%) All (%) Tumor Size (cm) 0 - 1 16 19 > 1 - 2 46 45 > 2 - 4 33 32 > 4 5 4 Patient Age (yr) < 50 29 34 ≥ 50 71 66

  28. B-14 Pre-Specified Endpoints • Primary • Distant Recurrence-Free Survival (DRFS)* • Secondary • Relapse-Free Survival (RFS) • Overall Survival (OS) *For primary analysis, patients censored at time of development of contralateral breast cancer, second non-breast cancer, or death without breast cancer recurrence

  29. 10 year DRFS = 85% B14-Results DRFS—All 668 Patients

  30. B-14 Results • First Primary Objective • Validate that 10 year DRFS in the low risk group (RS<18) is significantly better than 10 year DRFS in the high risk group (RS≥31)

  31. B-14 Results DRFS—Low, Intermediate and High RS Groups Risk Group % of 10-yr Rate 95% CI Patients Recurrence Low (RS<18) 51% 6.8% 4.0%, 9.6% Intermediate (RS 18-30) 22% 14.3% 8.3%, 20.3% High (RS≥31) 27% 30.5% 23.6%, 37.4% Test for the 10-year DRFS comparison between the Low and High risk groups: p<0.00001

  32. 338 pts 149 pts 181 pts B14-Results DRFS—Low, Intermediate, High RS Groups

  33. B-14 Results • Second Primary Objective • Validate that Recurrence Score remains a significant predictor of DRFS, after accounting for age and tumor size

  34. Cox Models for DRFS—Age, Size Alone vs. Age, Size + RS Variable Hazard Ratio 95% CI p-value Age ≥ 50 0.57 (0.39, 0.83) 0.004 Size > 2.0 cm 1.44 (0.99, 2.11) 0.058 p<0.00001 Age ≥ 50 0.71 (0.48, 1.05) 0.084 Size > 2.0 cm 1.26 (0.86, 1.85) 0.231 Recurrence Score 3.21 (2.23, 4.61) <0.00001 B-14 Results

  35. p<0.0001 338 pts 149 pts 181 pts B-14 Results—Relapse-Free Survival

  36. p<0.0001 338 pts 149 pts 181 pts B-14 Results—Overall Survival

  37. Recurrence Score and Tumor Grade • Tumor grade is subjective and varies between different readers • RS and tumor grade correlate, but only modestly • RS is more powerful, objective and reproducible

  38. Tumor Grade Correlates with Recurrence Tumor Grade and DRFS in B-14 (n = 668) DRFS p<0.0001

  39. Tumor Grade Concordance 43% Among Three Pathologists for B-14 NSABP, UCSF, Stanford Pathologists Overall Concordance = 43%

  40. Recurrence Score as a Continuous Predictor 95% CI 95% CI Paik et al, SABCS 2003 Paik et al, SABCS 2003

  41. Recurrence Score as a Continuous Predictor My RS is 30, What is the chance of recurrence within 10 yrs? 95% CI Paik et al, SABCS 2003

  42. Summary • The NSABP B-14 study shows that the Recurrence Score identifies a set of women, comprising over 50% of node-, ER+, tamoxifen-treated patients, who are at low risk of recurrence and are less likely to benefit from chemotherapy. • Met its prospectively defined endpoints • Assay success rate in this prospective multi-center study was 99% • Validates results of prior NSABP B-20 in similar population • Recurrence Score performance exceeds standard measures, such as age, tumor size, and tumor grade either in prognostic power or in reproducibility

  43. Case studies • Genomic Health • PharmGKB • Theranos

  44. PharmGKB • PharmGKB (Pharmacogenomics Knowledge Base) • Curated database of genotype and phenotype information • Shared resource for researchers • Developed at Stanford • Russ Altman • Teri Klein

  45. Case studies • Genomic Health • PharmGKB • Theranos

  46. Theranos • Theranos is a pre-IPO company whose goal is to analyze patient samples in real time, rather than at infrequent clinic visits • Use a small device (similar to devices for analyzing blood glucose) to collect and analyze molecular markers and/or drug levels in the patient samples (blood, urine) • Identify markers and levels that predict lack of efficacy or risk of adverse events

  47. Technical issues

  48. Phenotype (disease or drug response) is a function of: • Several million SNP’s • Expression of 30,000 + genes • Environment • Interactions among these variables

  49. With current technology, we rarely have enough data to understand these factors. • Can only look at a small number of variables. • Usually explain only a very small part of the phenotypic variability. • How much clinical utility?

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